El Niño and Extreme Atlantic Ocean Heat are About to Clash

Hurricane Florence, seen from the International Space Station in 2018. Atlantic hurricane season runs from June 1 to Nov. 30.
NASA

The Atlantic hurricane season starts on June 1, and forecasters are keeping a close eye on rising ocean temperatures, and not just in the Atlantic.

Globally, warm sea surface temperatures that can fuel hurricanes have been off the charts in the spring of 2023, but what really matters for Atlantic hurricanes are the ocean temperatures in two locations: the North Atlantic basin, where hurricanes are born and intensify, and the eastern-central tropical Pacific Ocean, where El Niño forms.

This year, the two are in conflict – and likely to exert counteracting influences on the crucial conditions that can make or break an Atlantic hurricane season. The result could be good news for the Caribbean and Atlantic coasts: a near-average hurricane season. But forecasters are warning that that hurricane forecast hinges on El Niño panning out.

Ingredients of a hurricane

In general, hurricanes are more likely to form and intensify when a tropical low-pressure system encounters an environment with warm upper-ocean temperatures, moisture in the atmosphere, instability and weak vertical wind shear.

Warm ocean temperatures provide energy for a hurricane to develop. Vertical wind shear, or the difference in the strength and direction of winds between the lower and upper regions of a tropical storm, disrupts the organization of convection – the thunderstorms – and brings dry air into the storm, inhibiting its growth.

How hurricanes form. National Geographic.

The Atlantic Ocean’s role

The Atlantic Ocean’s role is pretty straightforward. Hurricanes draw energy from warm ocean water beneath them. The warmer the ocean temperatures, the better for hurricanes, all else being equal.

Tropical Atlantic Ocean temperatures were unusually warm during the most active Atlantic hurricane seasons on recent record. The 2020 Atlantic hurricane season produced a record 30 named tropical cyclones, while the 2005 Atlantic hurricane season produced 28 named storms, a record 15 of which became hurricanes, including Katrina.

Two maps showing tropical cyclone tracks. The tracks correspond with warmer water temperatures in the sea surface temperature maps below.
The top images show where Atlantic tropical storms traveled in 2005, on the left, and in 2020, on the right. The lower images show the corresponding sea surface temperature anomalies for the August-October peak of the hurricane season compared with the August-October 1991-2020 average in degrees Celsius.
NOAA

How the Pacific Ocean gets involved

The tropical Pacific Ocean’s role in Atlantic hurricane formation is more complicated.

You may be wondering, how can ocean temperatures on the other side of the Americas influence Atlantic hurricanes? The answer lies in teleconnections. A teleconnection is a chain of processes in which a change in the ocean or atmosphere in one region leads to large-scale changes in atmospheric circulation and temperature that can influence the weather elsewhere.

Sea surface temperature anomalies in degrees Celsius observed during three El Niño events show differences in location and strength of ocean warming.
Three examples of of how sea surface temperatures in the tropical Pacific change during El Niño events.
Christina Patricola

One recurring pattern of tropical Pacific climate variability that initiates teleconnections is the El Niño-Southern Oscillation.

When the tropical eastern-central Pacific Ocean is unusually warm, El Niño can form. During El Niño events, the warm upper-ocean temperatures change the vertical and east-west atmospheric circulation in the tropics. That initiates a teleconnection by affecting the east-west winds in the upper atmosphere throughout the tropics, ultimately resulting in stronger vertical wind shear in the Atlantic basin. That wind shear can tamp down hurricanes.

Two illustrations of Walker Circulation patterns. El Niño reverses direction and strength compared with a neutral ENSO, or El Niño-Southern Oscillation.
How El Niño conditions affect the Walker Circulation’s air flow, which can affect weather around the world.
Fiona Martin/NOAA Climate.gov

That’s what forecasters are expecting to happen this summer. The latest forecasts show a 90% likelihood that El Niño will develop by August and stay strong through the fall peak of the hurricane season.

A tug of war between Atlantic and Pacific influences

My research and work by other atmospheric scientists has shown that a warm Atlantic and a warm tropical Pacific tend to counteract each other, leading to near-average Atlantic hurricane seasons.

Both observations and climate model simulations have shown that outcome. The National Oceanic and Atmospheric Administration’s 2023 forecast calls for a near-average 12 to 17 named storms, five to nine hurricanes and one to four major hurricanes. An earlier outlook from Colorado State University forecasters anticipates a slightly below-average season, with 13 named storms, compared with a climatological average of 14.4.

Map showing warmer than normal temperatures across the Gulf of Mexico and Atlantic Ocean south of the Virginia.
Sea surface temperature anomaly in degrees Celsius forecast for August to October 2023 shows a warm season relative to the 1991-2020 average for the same months.
Based on NCEP Climate Forecast System version 2 (CFSv2)

The wild cards to watch

Although tropical Atlantic and Pacific Ocean temperatures often inform skillful seasonal hurricane forecasts, there are other factors to consider and monitor.

First, will the forecast El Niño and Atlantic warming pan out? If one or the other does not, that could tip the balance in the tug of war between the influences.

The Atlantic Coast should be rooting for El Niño to develop as forecast, since such events often reduce hurricane impacts there. If this year’s expected Atlantic Ocean warming were instead paired with La Niña – El Nino’s opposite, characterized by cool tropical Pacific waters – that could have led to a record-breaking active season instead.

Two other factors are also important. The Madden-Julian Oscillation, a pattern of clouds and rainfall that travels eastward through the tropics on a time scale of 30 to 90 days, can either encourage or suppress tropical storm formation. And dust storms from the Saharan air layer, which contains warm, dry and dusty air from Africa, can suppress tropical cyclones.The Conversation

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Christina Patricola is Assistant Professor of Atmospheric Sciences at Iowa State University.